A disk of radius 5 cm carries a uniform surface charge density of 4 μC/m2. Find the electric field on the axis of the disk at distance of 0.03 cm
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QUESTION 16 A disk of radius 5 cm carries a uniform surface charge density of 4 μC/m. Find the exact electric field on the axis of the disk at a distance of 0.03 cm and compare this to the result for an infinite disk. 224,027 and 225,430 N/C for a finite and infinite disk, respectively. 224,530 and 225,430 N/C for a finite and infinite disk, respectively. 225,430 and 225,880 N/C for a finite and infinite disk, respectively 224,530 and 225,880...
A disk of radius 2.6 cm has a surface charge density of 6.9 μC/m2 on its upper face. What is the magnitude of the electric field produced by the disk at a point on its central axis at distance z = 12 cm from the disk?
Problem 8: Solve problem 21 on page 317 of Gilat's book 1. Program a function that calculates the integrand. 2. Use the MATLAB quad function in order to calculate the integral numerically. 21. The electric field E due to a charged circular disk at a point at a distance z along the axis of the disk is given by where σ is the charge density, , is the permittivity constant, e.-8.85 x 10-12 CON m2) and R is the radius...
A charged disk and a charged ring are centered at the origin in the free space as shown in figure 4. Bothe changed elements exists in the xy plane. The disk has a radius a and carries a uniform surface charge density of Ps. The ring has a radius 2a and carries a uniform line charge density Pe. Find the following: a) The electric field intensity on z-axis and determine where the electric field is zero b) The electric potential...
a). Find the electric field along the axis of a thin disk placed in the xy plane, at a distance z from the disk center (the field at distance z from center). It has a uniform charge of density σ and an outer radius R. b). Now consider a similar disk with annular shape, it is the disk in part (a) but with a concentric hole of radius R/2. Calculate the electric field along the z axis. c). Find electric...
A disk of radius 2.5 cm has a surface charge density of 5.3 µC/m2 on its upper face. What is the magnitude of the electric field produced by the disk at a point on its central axis at distance z = 11 cm from the disk?
34 A disk of radius 2.5 cm has a surface charge density of 5.3 C/m2 on its upper face. What is the magnitude of the electric field produced by the disk at a point on its central axis at distance z- 12 cm from the disk?
The figure shows two nonconducting spherical shells fixed in place. Shell 1 has uniform surface charge density +6.0 μC/m2 on its outer surface and radius 4.3 cm; shell 2 has uniform surface charge density +4.8 μC/m2 on its outer surface and radius 2.1 cm; the shell centers are separated by L = 12.8 cm. What is the x-component (with sign) of the net electric field at x = 2.1 cm?
The figure shows two nonconducting spherical shells fixed in place. Shell 1 has uniform surface charge density +5.2 μC/m2 on its outer surface and radius 3.6 cm , shell 2 has uniform surface charge density +3.1 μC/m2 on its outer surface and radius 1.9 cm; the shell centers are separated by L = 11.5 cm. what is the x-component (with sign) of the net electric field at x = 2.1 cm? Shell Shell
Two very large parallel sheets are 5.00 cm apart. Sheet A carries a uniform surface charge density of -6.80 μC/m2 , and sheet B, which is to the right of A, carries a uniform charge density of +12.1 μC/m2 . Assume that the sheets are large enough to be treated as infinite. PART C: Part E: Any help accounting for both of these questions would be very appreciated, please include the work and explanations to go along with them. Problem...